1. Organization WH, Ageing WHO, Unit LC. WHO: global report on falls prevention in older age. World Health Organization. 2008.
2. Salzman B. Gait and balance disorders in older adults. American family physician. 2010; 82(1): 61–8.
3. Massion J. Movement, posture and equilibrium: Interaction and coordination. Progress in Neurobiology. 1992; 38(1): 35–56.
4. Aruin AS, Latash M. The role of motor action in anticipatory postural adjustments studied with self-induced and externally triggered perturbations. Experimental Brain Research. 1995; 106(2): 291–300.
5. Li X, Aruin AS. The effect of short-term changes in the body mass on anticipatory postural adjustments. Experimental Brain Research. 2007; 181(2): 333–46.
7. Aruin AS, Kanekar N, Lee YJ, Ganesan M. Enhancement of anticipatory postural adjustments in older adults as a result of a single session of ball throwing exercise. Experimental Brain Research. 2015; 233(2): 649–55.
8. Chen LK, Liu LK, Woo J, et al. Sarcopenia in Asia: Consensus Report of the Asian Working Group for Sarcopenia. Journal of the American Medical Directors Association. 2014; 15(2): 95–101.
9. Jagdhane S, Kanekar N, S Aruin A. The effect of a four-week balance training program on anticipatory postural adjustments in older adults: a pilot feasibility study. Current aging science. 2016; 9(4): 295–300.
10. Aruin A, Shiratori T. Anticipatory postural adjustments while sitting: The effects of different leg supports. Experimental Brain Research. 2003; 151:46–53.
11. Hiraoka K, Kunimura H, Oda H, Kawasaki T, Sawaguchi Y. Rhythmic movement and rhythmic auditory cues enhance anticipatory postural adjustment of gait initiation. Somatosensory & Motor Research. 2020; 37(3): 213–21.
12. Kanekar N, Aruin AS. Improvement of anticipatory postural adjustments for balance control: effect of a single training session. Journal of Electromyography and Kinesiology. 2015; 25(2): 400–5.
13. Curuk E, Lee Y, Aruin AS. Individuals with stroke improve anticipatory postural adjustments after a single session of targeted exercises. Human Movement Science. 2020; 69:102559.
14. Boyer E, Caramiaux B, Hanneton S, Roby-Brami A, Houix O, Susini P, Bevilacqua F. Sensori-motor Learning in Movement-Sound Interactive Systems: a Review. 2014.
15. Myers JB, Wassinger CA, Lephart SM. Sensorimotor contribution to shoulder stability: effect of injury and rehabilitation. Manual Therapy. 2006; 11(3): 197–201.
17. McCrea DA, Rybak IA. Organization of mammalian locomotor rhythm and pattern generation. Brain Research Reviews. 2008; 57(1): 134–46.
18. Repp BH. Sensorimotor synchronization and perception of timing: effects of music training and task experience. Human Movement Science. 2010; 29(2): 200–13.
19. Repp BH, Su YH. Sensorimotor synchronization: a review of recent research (2006-2012). Psychonomic Bulletin & Review. 2013; 20:403–52.
20. Hogan N, Sternad D. On rhythmic and discrete movements: reflections, definitions and implications for motor control. Experimental Brain Research. 2007; 181:13–30.
24. Nombela C, Hughes LE, Owen AM, Grahn JA. Into the groove: can rhythm influence Parkinson’s disease? Neuroscience & Biobehavioral Reviews. 2013; 37(10): 2564–70.
25. Rochester L, Baker K, Hetherington V, et al. Evidence for motor learning in Parkinson’s disease: acquisition, automaticity and retention of cued gait performance after training with external rhythmical cues. Brain Research. 2010; 1319:103–11.
26. Kitatani R, Umehara J, Hirono T, Yamada S. Rhythmic auditory stimulation during gait adaptation enhances learning aftereffects and savings by reducing common neural drives to lower limb muscles. Journal of Neurophysiology. 2022; 128(5): 1324–36.
27. Farrow D, Abernethy B. Do expertise and the degree of perception—action coupling affect natural anticipatory performance? Perception. 2007; 32(9): 1127–39.
28. Zelic G, Varlet M, Kim J, Davis C. Influence of pacer continuity on continuous and discontinuous visuo-motor synchronisation. Acta Psychologica. 2016; 169:61–70.
29. Luchies CW, Schiffman J, Richards LG, Thompson MR, Bazuin D, DeYoung AJ. Effects of age, step direction, and reaction condition on the ability to step quickly. The Journals of Gerontology Series A: Biological Sciences and Medical Sciences. 2002; 57(4):M246–M249.
30. Patla A, Frank JS, Winter DA, Rietdyk S, Prentice S, Prasad S. Age-related changes in balance control system: initiation of stepping. Clinical Biomechanics. 1993; 8(4): 179–84.